Extracellular ATP and Toll-like receptor 2 agonists trigger in human monocytes an activation program that favors T helper 17.

Strategically-paired Toll-like receptor (TLR) ligands induce a unique dendritic cell (DC) phenotype that polarizes Th1 responses. We therefore investigated pairing single TLR ligands with a non TLR-mediated danger signal to cooperatively induce distinct DC properties from cultured human monocytes. Adenosine triphosphate (ATP) and the TLR2 ligand lipoteichoic acid (LTA) selectively and synergistically induced expression of IL-23 and IL-1ß from cultured monocytes as determined by ELISA assays. Flow cytometric analysis revealed that a sizable sub-population of treated cells acquired DC-like properties including activated surface phenotype with trans-well assays showing enhanced migration towards CCR7 ligands. Such activated cells also preferentially deviated, in an IL-23 and IL-1-dependent manner, CD4(pos) T lymphocyte responses toward the IL-22(hi), IL-17(hi)/IFN-γ(lo) Th17 phenotype in standard in vitro allogeneic sensitization assays. Although pharmacological activation of either ionotropic or cAMP-dependent pathways acted in synergy with LTA to enhance IL-23, only inhibition of the cAMP-dependent pathway antagonized ATP-enhanced cytokine production. ATP plus atypical lipopolysaccharide from P. gingivalis (signaling through TLR2) was slightly superior to E. coli-derived LPS (TLR4 ligand) for inducing the high IL-23-secreting DC-like phenotype, but greatly inferior for inducing IL-12 p70 production when paired with IFN-γ, a distinction reflected in activated DCs' ability to deviate lymphocytes toward Th1. Collectively, our data suggest TLR2 ligands encountered by innate immune cells in an environment with physiologically-relevant levels of extracellular ATP can induce a distinct activation state favoring IL-23- and IL-1ß-dependent Th17 type response.

Effect of multiple activation stimuli on the generation of Th1-polarizing dendritic cells.

It was originally reported that only a small fraction of total matured dendritic cells (DCs) produced interleukin (IL)-12, but it has never been determined whether different combinations of activating signals now shown to maximize secreted IL-12 do so through increasing output by the same IL-12 producers, or by recruiting additional cytokine-secreting cells. We therefore tested all combinations of bacterial lipopolysaccharide (LPS) (TLR4 ligand), R848 (TLR8 ligand), interferon (IFN)-γ, and CD40L for activating human monocyte-derived dendritic cells (DC), and determined by intracellular flow cytometry that enhanced IL-12 secretion was accomplished in large part by markedly increasing the proportion of cells producing IL-12, with the triple and quadruple combinations recruiting the most DC. This optimization requirement for multiple signals was not reflected in differential Toll-like receptor (TLR) expression by the cells. Interestingly, DCs activated with single TLR ligands plus IFN-γ were capable of responding with a second burst of IL-12 upon later CD40L stimulation, whereas DCs activated with R848 plus LPS were not, despite the trend of the latter for superior polarization of naive T cells toward IFN-γ-secreting Th1. These results have implications for the biology of IL-12-secreting DCs and choice of activation regimen for prospective use in DC-based immunotherapy.

Paired Toll-like receptor agonists enhance vaccine therapy through induction of interleukin-12.

Minimal requirements for generating effective immunity include the delivery of antigenic (signal 1) and costimulatory (signal 2) signals to T lymphocytes. Recently, a class of third signals, often delivered by antigen-presenting dendritic cells, has been shown to greatly enhance immune responses, especially against tumors. Among signal 3 factors, interleukin (IL)-12 is particularly effective and can be conditionally induced by agonists of Toll-like transmembrane receptors (TLR). In this study, we assessed the therapeutic effect of adjuvant TLR agonist administration upon the capacity of dendritic cell (DC)-tumor electrofusion hybrids to eradicate established MCA205 sarcomas in syngeneic mice. Paired, but not solitary combinations of polyinosine:polycytadilic acid (P[I:C]; TLR3 agonist) and CpG DNA (ODN1826l; TLR9 agonist) stimulated IL-12 secretion from DCs in vitro and synergized with vaccination to achieve potent tumor rejection. Therapeutic effects, however, required coadministration of paired TLR agonists and DC-tumor fusion hybrids. The administration of TLR agonists alone or with fusion vaccine induced transient splenomegaly but without apparent toxicity. The therapeutic effects of this immunization regimen were significantly abrogated through the neutralization of IL-12p70, indicating that production of this third signal was essential to the observed tumor regression. These results show the profound functional consequences of TLR cooperativity and further highlight the critical role of IL-12 in antitumor immunity.

STAT3- and STAT5-dependent pathways competitively regulate the pan-differentiation of CD34pos cells into tumor-competent dendritic cells.

The clinical outcomes of dendritic cell (DC)-based immunotherapy remain disappointing, with DCs often displaying a tenuous capacity to complete maturation and DC1 polarization in the tumor host. Surprisingly, we observed that the capacity for successful DC1 polarization, including robust IL12p70 production, could be regulated by STAT-dependent events even prior to DC differentiation. Exposure of CD34(pos) cells to single-agent granulocyte-macrophage colony-stimulating factor (GMCSF) induced multilineage, STAT5-dependent differentiation, including DCs that failed to mature in the absence of further exogenous signals. In contrast, Flt3L induced nearly global differentiation of CD34(pos) cells into spontaneously maturing DCs. IL-6 synergized with Flt3L to produce explosive, STAT3-dependent proliferation of phenotypically undifferentiated cells that nevertheless functioned as committed DC1 precursors. Such precursors not only resisted many tumor-associated immunosuppressants, but also responded to tumor contact or TGFbeta with facilitated DC maturation and IL12p70 production, and displayed a superior capacity to reverse tumor-induced T-cell tolerance. GMCSF preempted Flt3L or Flt3L plus IL-6 licensing by blocking STAT3 activation and promoting STAT5-dependent differentiation. Paradoxically, following overt DC differentiation, STAT5 enhanced whereas STAT3 inhibited DC1 polarization. Therefore, nonoverlapping, sequential activation of STAT3 and STAT5, achievable by sequenced exposure to Flt3L plus IL-6, then GMCSF, selects for multilog expansion, programming, and DC1 polarization of tumor-competent DCs from CD34(pos) cells.